Litcius/Paper detail

Programmable molecular transport achieved by engineering protein motors to move on DNA nanotubes

Ryota Ibusuki, Tatsuya MORISHITA, Akane Furuta, Shintaro Nakayama, Maki Yoshio, Hiroaki Kojima, Kazuhiro Oiwa, Ken’ya Furuta

2022Science78 citationsDOI

Abstract

Intracellular transport is the basis of microscale logistics within cells and is powered by biomolecular motors. Mimicking transport for in vitro applications has been widely studied; however, the inflexibility in track design and control has hindered practical applications. Here, we developed protein-based motors that move on DNA nanotubes by combining a biomolecular motor dynein and DNA binding proteins. The new motors and DNA-based nanoarchitectures enabled us to arrange the binding sites on the track, locally control the direction of movement, and achieve multiplexed cargo transport by different motors. The integration of these technologies realized microscale cargo sorters and integrators that automatically transport molecules as programmed in DNA sequences on a branched DNA nanotube. Our system should provide a versatile, controllable platform for future applications.

Topics & Concepts

Microscale chemistryMolecular motorIntegratorNanotechnologyDNAMotor proteinDyneinComputer scienceBiophysicsChemistryMaterials scienceCell biologyBiologyBiochemistryMicrotubuleMathematics educationMathematicsComputer networkBandwidth (computing)Advanced biosensing and bioanalysis techniquesMicrotubule and mitosis dynamicsRNA Interference and Gene Delivery